Dynamic and spectroscopic characteristics of atmospheric gliding arc in gas-liquid two-phase flow
In this study, an atmospheric alternating-current gliding arc device in gas-liquid two-phase flow has been developed for the purpose of waste water degradation. The dynamic behavior of the gas-liquid ...
In this study, an atmospheric alternating-current gliding arc device in gas-liquid two-phase flow has been developed for the purpose of waste water degradation. The dynamic behavior of the gas-liquid ...
Technique for analysis of interparticle interaction in nonideal dissipative systems with isotropic pair potentials
A new technique for determining interaction forces between the particles in nonideal dissipative systems with isotropic pair potentials is presented. This technique is based on solving of the inverse ...
A new technique for determining interaction forces between the particles in nonideal dissipative systems with isotropic pair potentials is presented. This technique is based on solving of the inverse ...
Dust negative ion acoustic shock waves in a dusty multi-ion plasma with positive dust charging current
Phys. Plasmas 16, 113701 (2009); doi:10.1063/1.3257171
Published 4 November 2009
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Recent analysis of Mamun et al. [ Phys. Lett. A 373, 2355 (2009)], who considered electrons, light positive ions, heavy negative ions, and extremely massive (few micron size) charge fluctuating dust, has been extended by positive dust charging current, i.e., considering the charging currents for positively charged dust grains. A dusty multi-ion plasma system consisting of electrons, light positive ions, negative ions, and extremely massive (few micron size) charge fluctuating stationary dust have been considered. The electrostatic shock waves associated with negative ion dynamics and dust charge fluctuation have been investigated by employing the reductive perturbation method. It has been shown that the dust charge fluctuation is a source of dissipation and is responsible for the formation of dust negative ion acoustic (DNIA) shock structures. The basic features of such DNIA shock structures have been identified. The findings of this investigation may be useful in understanding the laboratory phenomena and space dusty plasmas.
©2009 American Institute of Physics
| History: | Received 2 September 2009; accepted 9 October 2009; published 4 November 2009 |
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http://link.aip.org/link/?PHPAEN/16/113701/1 |
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REFERENCES (17)
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